Method of and system for enhanced data storage

ABSTRACT

A method of and system for enhanced storage allows more data to be backed up than would otherwise be possible. Instead of storing uncompressed base images and incremental images, differentials of non-current base images are compressed and stored. Furthermore, incremental images that are older than the current base image are removed. By only saving differential base images that are compressed, aside from the newest base image, and deleting older incremental images, a significant amount of space is saved. A removable drive is used as temporary storage in the process of generating a compressed differential base for previous base images. Additionally, a process ensures that previous base images are differentials of the most recent base image and not each other.

FIELD OF THE INVENTION

The present invention relates to the field of computing. Morespecifically, the present invention relates to the field of data backup.

BACKGROUND OF THE INVENTION

In information technology, backup refers to the copying of data so thatthese additional copies may be restored after a data loss event. Backupsare useful primarily for two purposes: to restore a computer to anoperational state following a disaster (called disaster recovery) and torestore small numbers of files after they have been accidentally deletedor corrupted. Backups differ from archives in the sense that archivesare the primary copy of data and backups are a secondary copy of data.Backup systems differ from fault-tolerant systems in the sense thatbackup systems assume that a fault will cause a data loss event andfault-tolerant systems assume a fault will not. Backups are typicallythat last line of defense against data loss and consequently the leastgranular and the least convenient to use.

Since a backup system contains at least one copy of all data worthsaving, the data storage requirements are considerable. Organizing thisstorage space and managing the backup process is a complicatedundertaking.

Any backup strategy starts with a concept of a data repository. Thebackup data needs to be stored somehow and probably should be organizedto a degree. It is able to be as simple as a sheet of paper with a listof all backup tapes and the dates they were written or a moresophisticated setup with a computerized index, catalog or relationaldatabase. Different repository models have different advantages. This isclosely related to choosing a backup rotation scheme.

An unstructured repository may simply be a stack of floppy disks or CD-Rmedia with minimal information about what was backed up and when. Thisis the easiest to implement, but probably the least likely to achieve ahigh level of recoverability.

A Full plus Incremental repository aims to make storing several copiesof the source data more feasible. At first, a full backup (of all files)is taken. After that an incremental backup (of only the files that havechanged since the previous full or incremental backup) is taken.Restoring whole systems to a certain point in time would requirelocating the full backup taken previous to that time and all theincremental backups taken between that full backup and the particularpoint in time to which the system is supposed to be restored. This modeloffers a high level of security that something is able to be restoredand is able to be used with removable media such as tapes and opticaldisks. The downside is dealing with a long series of incrementals andthe high storage requirements.

A Full plus Differential backup differs from a Full plus Incremental inthat after the full backup is taken, each partial backup captures allfiles created or changed since the full backup, even though some mayhave been included in a previous partial backup. Its advantage is that arestore involves recovering only the last full backup and thenoverlaying it with the last differential backup.

A Minor plus Reverse Incrementals repository is similar to a Full plusIncrementals repository. The difference is instead of an aging fullbackup followed by a series of incrementals, this model offers a mirrorthat reflects the system state as of the last backup and a history ofreverse incrementals. One benefit of this is it only requires an initialfull backup. Each incremental backup is immediately applied to the minorand the files they replace are moved to a reverse incremental. Thismodel is not suited to use removable media since every backup must bedone in comparison to the minor.

A continuous data protection model takes backup a step further, andinstead of scheduling periodic backups, the system immediately logsevery change on the host system. This is generally done by saving byteor block-level differences rather than file-level differences. Itdiffers from simple disk minoring in that it enables a roll-back of thelog and thus restore of old image of data.

Deciding what to back up at any given time is a harder process than itseems. By backing up too much redundant data, the data repository willfill up too quickly. If enough data is not backed up, criticalinformation is able to get lost. The key concept is to only back upfiles that have changed.

Copying the file system that holds the files to be backed up to anotherlocation is one option. This usually involves unmounting the file systemand running a program like dump. This is also known as a raw partitionbackup. This type of backup has the possibility of running faster than abackup that simply copies files. A feature of some dump software is theability to restore specific files from the dump image.

Some file systems have an archive bit for each file that says it wasrecently changed for copies of only changed files. Some backup softwarelooks at the date of the file and compares it with the last backup, todetermine whether the file was changed.

Block level incremental copying is a more sophisticated method ofbacking up changes to files by only backing up the blocks within thefile that have changed. This requires a higher level of integrationbetween the file system and the backup software.

A versioning file system keeps track of all changes to a file and makesthose changes accessible to the user. Generally this gives access to anyprevious version, all the way back to the file's creation time. Anexample of this is Wayback for the Linux OS.

If a computer system is in use while it is being backed up, thepossibility of files being open for reading or writing is real. If afile is open, the contents on disk may not correctly represent what theowner of the file intends. This is especially true for database files ofall kinds.

When attempting to understand the logistics of backing up open files,one must consider that the backup process could take several minutes toback up a large file such as a database. In order to back up a file thatis in use, it is vital that the entire backup represent a single-momentsnapshot of the file, rather than a simple copy of a read-through. Thisrepresents a challenge when backing up a file that is constantlychanging. Either the database file must be locked to prevent changes, ora method must be implemented to ensure that the original snapshot ispreserved long enough to be copied, all while changes are beingpreserved. Backing up a file while it is being changed, in a manner thatcauses the first part of the backup to represent data before changesoccur to be combined with later parts of the backup after the changeresults in a corrupted file that is unusable, as most large filescontain internal references between their various parts that must remainconsistent throughout the file.

A snapshot is an instantaneous function of some storage systems thatpresents a copy of the file system as if it was frozen in a specificpoint in time, often by copy-on-write mechanism. Quiescing to consistentstate (e.g. closing all files) for a short time, taking a snapshot, thenresuming data change process and running the backup on the snapshot isan effective way to work around this problem. A snapshot itself ishardly a backup, as it does not protect from disk hardware failure.

Many backup software packages feature the ability to backup open files.Some simply check for openness and try again later.

For cold database backup, during a cold backup the database is closed orlocked and not available to users. All files of the database are copied(image copy). The data files do not change during the copy so thedatabase is in sync upon restore.

Some database management systems offer a means to generate a backupimage of the database while it is online and usable (“hot”). Thisusually includes an inconsistent image of the data files plus a log ofchanges made while the procedure is running. Upon a restore, the changesin the log files are reapplied to bring the database in sync.

Not all information stored on the computer is stored in files.Accurately recovering a complete system from scratch requires keepingtrack of this non-file data also. System specifications are needed toprocure an exact replacement after a disaster. Each file's permissions,owner, group, ACLs, and any other metadata need to be backed up for arestore to properly recreate the original environment. The layout of theoriginal disk, as well as partition tables and file system settings, isneeded to properly recreate the original system. The boot sector is ableto sometimes be recreated more easily than saving it. Still, it usuallyis not a normal file and the system will not boot without it.

It is frequently useful to manipulate the backed up data to optimize thebackup process. These manipulations are able to improve backup speed,restore speed, data security, and media usage. Various schemes are ableto be employed to shrink the size of the source data to be stored sothat less storage space is used. Compression is frequently a built-infeature of tape drive hardware or other storage hardware.

When multiple similar systems are backed up to the same destinationstorage device, there exists the potential for much redundancy withinthe backed up data. For example, if 20 Windows® workstations were backedup to the same data repository, they might share a common set of systemfiles. The data repository only needs to store one copy of those filesto be able to restore any one of those workstations. This technique isable to be applied at the file level or even on raw blocks of data,potentially resulting in a massive reduction in required storage space.

Sometimes backup jobs are duplicated to a second set of storage media.This is able to be done to rearrange the backup images to optimizerestore speed, to have a second copy for archiving in a differentlocation or on a different storage medium.

High capacity removable storage media such as backup tapes present adata security risk if they are lost or stolen. Encrypting the data onthese media is able to mitigate this problem, but presents new problems.First, encryption is a CPU intensive process that is able to slow downbackup speeds. Second, once data has been encrypted, it is able to notbe effectively compressed (although since redundant data makescryptanalytic attacks easier many encryption routines compress the dataas an integral part of the encryption process). Third, the security ofthe encrypted backups is only as effective as the security of the keymanagement policy.

Sometimes backup jobs are copied to a staging disk before being copiedto tape. This is able to be useful if there is a problem matching thespeed of the final destination device with the source system as isfrequently faced in network-based backup systems.

Many backup programs make use of checksums or hashes to validate thatthe data was accurately copied. These offer several advantages. First,they allow data integrity to be verified without reference to theoriginal file: if the file as stored on the backup medium has the samechecksum as the saved value, then it is very probably correct. Second,some backup programs are able to use checksums to avoid making redundantcopies of files, to improve backup speed. This is particularly usefulfor the de-duplication process.

SUMMARY OF THE INVENTION

A method of and system for enhanced storage allows more data to bebacked up than would otherwise be possible. Instead of storinguncompressed base images and incremental images, differentials ofnon-current base images are compressed and stored. Furthermore,incremental images that are older than the current base image areremoved. By only saving differential base images that are compressed,aside from the newest base image, and deleting older incremental images,a significant amount of space is saved. A removable drive is used astemporary storage in the process of generating a compressed differentialbase for previous base images. Additionally, a process ensures thatprevious base images are differentials of the most recent base image andnot each other.

In one aspect, a method of providing enhanced data storage comprisesstoring a set of compressed base images and an uncompressed base imageon a main storage, writing a new base image to an additional storage,compressing the uncompressed base image based on the new base image andmoving the new base image to the main storage. A set of incrementalimages are stored on the main storage. Compressing the uncompressed baseimage based on the new base image includes differential compression. Theset of compressed base images are differentially compressed. The mainstorage and the additional storage are contained within a storageappliance. The additional storage is temporary storage. Additionally,the additional storage is a removable drive.

In another aspect, a method of synchronizing compressed base images withan uncompressed base image comprises storing an N−1 compressed baseimage on a temporary storage, wherein N is initially 0, decompressing afirst N−2 compressed base image into an N−2 uncompressed base imageusing the N−1 compressed base image on the temporary storage,compressing the N−2 uncompressed base image into a second N−2 compressedbase image using a current base image and replacing the first N−2compressed base image with the second N−2 compressed base image.Compressed includes differentially compressed. The method furthercomprises repeating the steps while decreasing N each time until all ofthe compressed base images are based on the current base image. Themethod runs as a background process. The method automatically beginsafter the current base image is replaced by a new base image. Thetemporary storage is a removable drive.

In yet another aspect, a system for providing enhanced data storagecomprises a computing device and a storage appliance coupled to thecomputing device, wherein the storage appliance further comprises a mainstorage component for storing a set of compressed base images and anuncompressed base image and a removable storage component coupled to themain storage component for temporarily storing base images. The mainstorage stores a set of incremental images. The removable storagecomponent temporarily stores a new uncompressed base image while theuncompressed current base image is compressed using the new uncompressedbase image. The removable storage component temporarily stores an N−1compressed base image, while an N−2 compressed base image isdecompressed and then the decompressed N−2 base image is re-compressedbased on a current base image, wherein N starts at 0 and decreases untilall of the compressed base images are based on the current base image.The storage appliance contains a backup application for initiating abackup sequence which includes storing a base image on the storageappliance. The storage appliance contains a background application forensuring all of the compressed base images are based on the uncompressedbase image. The computing device contains a backup application forinitiating a backup sequence which includes storing a base image on thestorage appliance. The computing device is selected from the groupconsisting of a personal computer, a server, a PDA, a laptop, a gamingconsole and a mobile phone.

In another aspect, an apparatus for providing enhanced data storagecomprises a main storage component for storing a set of compressed baseimages and an uncompressed base image and a removable storage componentcoupled to the main storage component for temporarily storing baseimages. The main storage stores a set of incremental images. Theremovable storage component temporarily stores a new uncompressed baseimage while the uncompressed current base image is compressed using thenew uncompressed base image. The removable storage component temporarilystores an N−1 compressed base image, while an N−2 compressed base imageis decompressed and then the decompressed N−2 base image isre-compressed based on a current base image, wherein N starts at 0 anddecreases until all of the compressed base images are based on thecurrent base image. The storage appliance contains a backup applicationfor initiating a backup sequence which includes storing a base image onthe storage appliance. The storage appliance contains a backgroundapplication for ensuring all of the compressed base images are based onthe uncompressed base image.

In yet another aspect, a network of devices for providing enhanced datastorage comprises a network, a plurality of computing devices forsending data to be backed up and a storage appliance coupled to theplurality of computing devices through the network, wherein the storageappliance backs up the data from the plurality of computing devices andfurther comprises a main storage component for storing a set ofcompressed base images and an uncompressed base image and a removablestorage component coupled to the main storage component for temporarilystoring base images. The main storage stores a set of incrementalimages. The removable storage component temporarily stores a newuncompressed base image while the uncompressed current base image iscompressed using the new uncompressed base image. The removable storagecomponent temporarily stores an N−1 compressed base image, while an N−2compressed base image is decompressed and then the decompressed N−2 baseimage is re-compressed based on a current base image, wherein N startsat 0 and decreases until all of the compressed base images are based onthe current base image. The storage appliance contains a backupapplication for initiating a backup sequence which includes storing abase image on the storage appliance. The storage appliance contains abackground application for ensuring all of the compressed base imagesare based on the uncompressed base image. Each of the plurality ofcomputing devices contains a backup application for initiating a backupsequence which includes storing a base image on the storage appliance.The plurality of computing devices are selected from the groupconsisting of personal computers, servers, PDAs, laptops, gamingconsoles and mobile phones.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an exemplary block diagram of relative storagereduction using base image compression.

FIG. 2 illustrates an exemplary block diagram of relative storagereduction using base image compression with enhancements.

FIG. 3 illustrates a graphical and textual flowchart of a process ofadding a new image to a storage appliance and then compressing a priorbase image using the new image as the compression base.

FIG. 4 illustrates a flowchart of a process of synchronizing images witha current image.

FIG. 5A illustrates a graphical representation of a computing devicecoupled to a storage appliance.

FIG. 5B illustrates a graphical representation of a network of devicescoupled to a storage appliance.

FIG. 6 illustrates a block diagram of a storage appliance.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

A method of and system for enhanced data storage is described herein. Astorage appliance has several functions, one of which includes storageof server and/or personal computer backup images. The backup functionrequires extensive amounts of storage since it is preferable to storemultiple backups. The enhanced data storage is a storage methodologyincluding compression techniques, enhancements to data purge routinesand use of removable drives as extended temporary storage. Theseimprovements greatly enlarge the storage capabilities of a storageappliance. For example, a storage appliance utilizing a standard backupmethodology is capable of storing 200 to 300 GB of data based on a 50%compression ratio. However, utilizing the enhanced data storage, thebackup storage capacity is able to be increased 2 to 3 times that of thestandard methodology, thus potentially allowing nearly 1 TB of data tobe stored.

The storage appliance stores image backups on RAID storage drives,preferably. To protect a customer's data, the storage appliance is ableto retain multiple backup periods of data. Each server's backup isstored as a base image, and then incremental backups are generated andstored. These incremental backups are much smaller since they aredifferential images, storing only differences compared to the baseimage. These incremental backups are taken as often as desired toprovide a necessary level of protection.

The methods implemented to maximize the storage of the storage applianceinclude storage of base image files as differentials, similar to thebackup incrementals, extending purge algorithms to allow anadministrator to purge differentials and using additional storage suchas a removable drive as a temporary storage drive to hold uncompresseddata before and after compression.

Base image files stored by image backup technologies are designed tosupport differential compression, even though image files are compressedby backup software. This provides an opportunity to store multiplecopies of base backup images with additional generations of image filesto be compressed to about the size of daily differential snapshot files.

To compress the image files further, which are already compressed,requires a compression technique where only the differences of two filesare stored for each generation. For example, if a first image file and asecond image file are the same, except that the second image file alsocontains data X, then data X is all that is stored for the second imagefile. Then, later, by using a difference, or delta method, the originaluncompressed file is able to be reconstructed by applying thedifferential file to the source file.

The efficiency of this compression algorithm depends on each base imagebeing similar to each new generation. In almost all server and personalcomputer images, this is the case. The operating systems, applications,and most of the data do not change from month to month, so this repeateddata does not have to be replicated.

FIG. 1 illustrates an exemplary block diagram of relative storagereduction using base image compression. Although not drawn to scale,with the same amount of base images and sets of incremental images,clearly the base image compression methodology utilizes less storagespace than the standard backup scheme. As described above, since thebase images are compressed (aside from the most current base image) andonly delta images are stored, the base image compression methodologysaves a significant amount of storage space.

An issue with base image compression storage is that the retrieval ofprior generations requires decompression, which is slower than directaccess. However, since the current base image is not compressed, whichis the most likely accessed image, this issue is not very significant.

Another issue with base image compression is that prior base imagegenerations are based on the next and newer generation. Therefore, toretrieve data from several generations back would require decompressingeach successive generation. This issue is resolved by generating abackground process which expands prior generations and recompressesthese images based on the latest uncompressed base image. This wouldmake access to prior images require only a single decompression.

When loading new base images onto main system drives of a storageappliance, there is a need for temporary additional storage. Since aprior image becomes compressed, the storage where the uncompressed imagewas stored would be wasted on the main storage drive. In cases where abase image file requires a large percentage of the available drive,resolving this issue would greatly extend the storage capacity.

This issue is alleviated by writing initial backups to an additionalstorage such as a removable drive initially, and then compressing theprior image before moving the new base image onto the main systemdrives.

Since incremental backups are kept in the current backup period forbusiness protection, but prior incremental backups are only retained toallow for recovery of single user files, such as accidentally deletedfiles; allowing users to purge periodic incremental backups would alsogreatly extend the storage capacity of the whole system.

FIG. 2 illustrates an exemplary block diagram of relative storagereduction using base image compression with enhancements. Although notdrawn to scale, with the same amount of base images and sets ofincremental images, clearly the base image compression methodologyutilizes less storage space than the standard backup scheme.Furthermore, by implementing an enhanced purge routine, even morestorage space is saved.

An administrator is given the capability of selecting retention periodsfor locally storing incremental files. The overall storage gain shown inthe FIG. 2 is over three times. Using the removable drive for temporarystorage also gains the ability to store backup images of servers where asingle backup image is very large, which is typical of large Exchangedatabases or on file servers.

FIG. 3 illustrates a graphical and textual flowchart of a process ofadding a new image to a storage appliance and then compressing a priorbase image using the new image as the compression base. In the step 300,a system (e.g. a storage appliance) stores a base image file,incremental images and compressed base image files. The compressed baseimage files are compressed using a file comparison algorithm which thenstores the differences only. A decompression algorithm uses the baseimage file and applies the differences to generate a complete image filewhen it is time to decompress a compressed base image file. In the step302, backup software writes a new image file to a removable drive wherethere is ample space. The new image file is able to be written anywherethere is sufficient temporary storage available. In the step 304, acurrent generation image is compressed into a delta (differences)compressed image file. The current generation image is compressed bycomparing the current generation image with the new generation image anddetermining the differences. In the step 306, the new generation file isremoved from the removable drive, either by copy and deletion or bymovement to the storage appliance.

When image files are compressed using the method above, the priorgenerations are compressed using a prior (and compressed) image. Todecompress these files requires decompressing the source file, thendecompressing the file image. Prior generations going back would becompressed using the next newer image. Decompressing images severalgenerations back are able to become an inordinately long process.Therefore, a solution to this is a background process which is able torun and bring prior generations up to date by re-compressing imagesusing the latest generation base image.

FIG. 4 illustrates a flowchart of a process of synchronizing images witha current image. The problem is that when a base image is initiallyloaded, and the prior base image is compressed as a (−1) generation, a(−2) generation is still compressed via the (−1) generation which meanstwo steps of decompression would be required to decompress the (−2)generation. In the step 400, an initial configuration of a storageappliance is determined. For example, it is determined that theconfiguration contains 2 compressed images, sets of incremental imagesand a current image. If the initial configuration is already known, thenthe step 400 is able to be skipped. In the step 402, the (−1) image isstored temporarily. Preferably, the (−1) image is temporarily stored ina removable drive; however, any storage location is possible. The (−2)image is then decompressed in the temporary storage using the (−1)image. Large image files are split into smaller pieces, so this step isable to be iterative if necessary. In some embodiments, storing the (−1)image and decompressing are two separate steps. In the step 404, thedecompressed (−2) version is then compressed using the (0) current imagefile and then replaces the older (−2) file. In some embodiments,compressing the decompressed version and replacing the file are twoseparate steps. In the step 406, the process repeats for each of theprior versions, if any, (e.g. (−3), (−4)). Preferably, this processautomatically begins after a new base image replaces a current baseimage.

FIG. 5A illustrates a graphical representation of a computing devicecoupled to a storage appliance. A storage appliance 500 is coupled to acomputing device 506. The storage appliance 500 implements and enablesthe above-described methodology of storing backup data more efficiently.The storage appliance 500 includes a main storage 502 and removabledrive 504 which are utilized in the backup process as described above.In some embodiments, additional storage instead of a removable drive isincluded.

The computing device 506 couples to the storage appliance 500 directlyor through a network. In some embodiments, the coupling is wired, and insome embodiments, the coupling is wireless. The computing device 506 isable to be a personal computer, a server, a PDA, a laptop, a gamingconsole, a mobile phone or any other computing device that needs databacked up.

FIG. 5B illustrates a graphical representation of a network of devicescoupled to a storage appliance. A storage appliance 500 is coupled to aset of computing devices 506, 508, 510, 512. The storage appliance 500implements and enables the above-described methodology of storing backupdata more efficiently. The storage appliance 500 includes a main storage502 and removable drive 504 which are utilized in the backup process asdescribed above. In some embodiments, additional storage instead of aremovable drive is included.

The computing devices 506, 508, 510, 512 couple to the storage appliance500 through a network 514. In some embodiments, the coupling is wired,and in some embodiments, the coupling is wireless. The computing devices506, 508, 510, 512 are able to be a personal computer, a server, a PDA,a laptop, a gaming console, a mobile phone or any other computing devicethat needs data backed up.

Since backing up a network of devices is slightly more complicated thanbacking up a single device, additional steps are taken to ensure fulland proper back up of each device. For example, if all of the computingdevices attempt to back up their data at the same time, a temporarystorage such as a removable drive may not have sufficient capacity tohandle the backups all at once. Therefore, scheduling is able to beprovided to ensure each computing device is backed up at a specifiedtime. Furthermore, since each computing device will have a differentbase image as well as different incremental images, the images areseparated to avoid any data corruption. In some embodiments, the mainstorage on the storage appliance is partitioned so that each computingdevice has its own partition for backup. In other embodiments, othersteps are taken to avoid data corruption. Also, in some embodiments,additional storage appliances are utilized to back up the data.

FIG. 6 illustrates a block diagram of a storage appliance. A storageappliance 600 contains standard server components including a networkinterface 602, a memory 604, a central processing unit 606, a system bus608 and storage 610 in addition to other standard computing components.Furthermore, the storage appliance 600 is able to have multiple of eachof these components. The storage 610 is able to be any storageimplementation such as a hard disk drive, RAID, or another form ofstorage. The storage appliance also includes one or more removabledrives 612 or another form of additional storage. A backup application614 implements the above-described methodology of more efficientlystoring backed up data. A background application 616 is the process thatruns in the background to keep the differential images up-to-date basedon the most recent image. Furthermore, additional applications areincluded within the storage appliance 600 to implement the improvedstorage methodology such as a user interface to allow users to purgedata that no longer needs to be backed up.

To utilize the enhanced data storage, one or more computing devices arecoupled to a storage appliance. Periodically, the data on the one ormore computing devices is backed up onto the storage appliance as animage. Initially, a first base image is not compressed so that it isable to be retrieved relatively quickly if necessary. However,subsequent backups mean that multiple base images are backed up on thestorage appliance. To minimize the total size of the backups, when a newimage is backed up, the current base image is modified to only store adifferential image based on the new base image. Therefore, the only fulluncompressed image is the new base image. Additional storage such as aremovable drive is used to perform the differential compression. Thissaves a significant amount of space in the main storage. Furthermore, apurge operation is permitted where users and/or administrators purgeincremental data when it no longer needs to be backed up, thus savingmore space. Additionally, to make the retrieval of data more efficient,instead of keeping each differential base image based on each priorimage, a background operation decompresses and recompresses eachdifferential base image based on the most recent base image. The backup,differential compression, purging and background processes are able tofunction with or without user intervention.

In operation, the enhanced data storage not only stores a most recentimage of a computing device, but also previous images in addition toincremental images. Therefore, to store all of these backups, asignificant amount of storage would normally be required, but with theenhanced data storage, storage space is saved utilizing differentials,compression and purging.

For example, a server is coupled to a storage appliance implementing theenhanced data storage methodology. An administrator configures thestorage appliance to save images of the server on a monthly basis inaddition to storing incremental images more often. After a month passes,a first base image is backed up on a main storage of the storageappliance. Incremental images are copied to the storage appliance in thesubsequent days. After a second month passes, a second base image isbacked up. The second base image is first stored on a removable drive.The first base image is then compared with the second base image, andonly a differential of the first base image is stored and compressed.The uncompressed first base image is deleted. The second base image isthen moved to the main storage and is deleted from the removable drive.Additional incremental images are copied again in subsequent days.Incremental images stored before the current base image are purged asdesired. After a third month passes, the process occurs again ofmodifying the current base image (e.g. the second base image) to adifferential base image and then storing the full new base image (e.g.the third base image). At some point, particularly when the storageappliance has free resources, a background application decompresses thefirst differential base image and recompresses it based on the newestbase image (e.g. the third base image). The processes continue to repeatas time passes such that previous base images are differentials and arecompressed while the newest base image is full and uncompressed.Furthermore, the previous base images are continuously uncompressed andrecompressed differentials of the newest base image instead of eachother.

In some embodiments, the storage appliance is very basic storage, andthe applications are stored on another device such as a server where theapplications control the storage appliance remotely. This allows thestorage appliance to be a very inexpensive “dumb” machine yet performcomplex storage tasks. For instance, applications to make a backup areable to be on the server in addition to the applications todifferentially compress as well as decompress and recompress the baseimages.

The present invention has been described in terms of specificembodiments incorporating details to facilitate the understanding ofprinciples of construction and operation of the invention. Suchreference herein to specific embodiments and details thereof is notintended to limit the scope of the claims appended hereto. It will bereadily apparent to one skilled in the art that other variousmodifications may be made in the embodiment chosen for illustrationwithout departing from the spirit and scope of the invention as definedby the claims.

1. A method of providing enhanced data storage, comprising: a. storing aset of compressed base images and an uncompressed base image on a mainstorage; b. writing a new base image to an additional storage; c.compressing the uncompressed base image based on the new base image; andd. storing the new base image.
 2. The method as claimed in claim 1wherein a set of incremental images are stored on the main storage. 3.The method as claimed in claim 1 wherein compressing the uncompressedbase image based on the new base image includes differentialcompression.
 4. The method as claimed in claim 1 wherein the set ofcompressed base images are differentially compressed.
 5. The method asclaimed in claim 1 wherein the main storage and the additional storageare contained within a storage appliance.
 6. The method as claimed inclaim 1 wherein the additional storage is temporary storage.
 7. Themethod as claimed in claim 1 wherein the additional storage is aremovable drive.
 8. A method of synchronizing compressed base imageswith an uncompressed base image, comprising: a. storing an N−1compressed base image on a temporary storage, wherein N is initially 0;b. decompressing a first N−2 compressed base image into an N−2uncompressed base image; c. compressing the N−2 uncompressed base imageinto a second N−2 compressed base image using a current base image; andd. storing the second N−2 compressed base image.
 9. The method asclaimed in claim 8 wherein compressed includes differentiallycompressed.
 10. The method as claimed in claim 8 further comprisingrepeating a-d while decreasing N each time until all of the compressedbase images are based on the current base image.
 11. The method asclaimed in claim 8 wherein the method runs as a background process. 12.The method as claimed in claim 8 wherein the method automatically beginsafter the current base image is replaced by a new base image.
 13. Themethod as claimed in claim 8 wherein the temporary storage is aremovable drive.
 14. A system for providing enhanced data storage,comprising: a. a computing device; and b. a storage appliance coupled tothe computing device, wherein the storage appliance further comprises:i. a main storage component for storing a set of compressed base imagesand an uncompressed base image; and ii. a removable storage componentcoupled to the main storage component for temporarily storing baseimages; wherein the removable storage component temporarily stores anN−1 compressed base image while an N−2 compressed base image isdecompressed, wherein the decompressed N−2 base image is re-compressedbased on a current base image.
 15. The system as claimed in claim 14wherein the main storage stores a set of incremental images.
 16. Thesystem as claimed in claim 14 wherein the removable storage componenttemporarily stores a new uncompressed base image while the uncompressedcurrent base image is compressed using the new uncompressed base image.17. (canceled)
 18. The system as claimed in claim 14 wherein the storageappliance contains a backup application for initiating a backup sequencewhich includes storing a base image on the storage appliance.
 19. Thesystem as claimed in claim 14 wherein the storage appliance contains abackground application for ensuring all of the compressed base imagesare based on the uncompressed base image.
 20. The system as claimed inclaim 14 wherein the computing device contains a backup application forinitiating a backup sequence which includes storing a base image on thestorage appliance.
 21. The system as claimed in claim 14 wherein thecomputing device is selected from the group consisting of a personalcomputer, a server, a PDA, a laptop, a gaming console and a mobilephone.
 22. An apparatus for providing enhanced data storage, comprising:a. a main storage component for storing a set of compressed base imagesand an uncompressed base image; and b. a removable storage componentcoupled to the main storage component for temporarily storing baseimages; wherein the removable storage component temporarily stores anN−1 compressed base image while an N−2 compressed base image isdecompressed, wherein the decompressed N−2 base image is re-compressedbased on a current base image.
 23. The apparatus as claimed in claim 22wherein the main storage stores a set of incremental images.
 24. Theapparatus as claimed in claim 22 wherein the removable storage componenttemporarily stores a new uncompressed base image while the uncompressedcurrent base image is compressed using the new uncompressed base image.25. (canceled)
 26. The apparatus as claimed in claim 22 wherein thestorage appliance contains a backup application for initiating a backupsequence which includes storing a base image on the storage appliance.27. The apparatus as claimed in claim 22 wherein the storage appliancecontains a background application for ensuring all of the compressedbase images are based on the uncompressed base image.
 28. A network ofdevices for providing enhanced data storage, comprising: a. a network;b. a plurality of computing devices for sending data to be backed up;and c. a storage appliance coupled to the plurality of computing devicesthrough the network, wherein the storage appliance backs up the datafrom the plurality of computing devices and further comprises: i. a mainstorage component for storing a set of compressed base images and anuncompressed base image; and ii. a removable storage component coupledto the main storage component for temporarily storing base images;wherein the removable storage component temporarily stores an N−1compressed base image while an N−2 compressed base image isdecompressed, wherein the decompressed N−2 base image is re-compressedbased on a current base image.
 29. The network of devices as claimed inclaim 28 wherein the main storage stores a set of incremental images.30. The network of devices as claimed in claim 28 wherein the removablestorage component temporarily stores a new uncompressed base image whilethe uncompressed current base image is compressed using the newuncompressed base image.
 31. (canceled)
 32. The network of devices asclaimed in claim 28 wherein the storage appliance contains a backupapplication for initiating a backup sequence which includes storing abase image on the storage appliance.
 33. The network of devices asclaimed in claim 28 wherein the storage appliance contains a backgroundapplication for ensuring all of the compressed base images are based onthe uncompressed base image.
 34. The network of devices as claimed inclaim 28 wherein each of the plurality of computing devices contains abackup application for initiating a backup sequence which includesstoring a base image on the storage appliance.
 35. The network ofdevices as claimed in claim 28 wherein the plurality of computingdevices are selected from the group consisting of personal computers,servers, PDAs, laptops, gaming consoles and mobile phones.
 36. A systemfor providing enhanced data storage, comprising: a. a computing device;and b. a storage appliance coupled to the computing device, wherein thestorage appliance further comprises: i. a main storage component forstoring a set of compressed base images and an uncompressed base image;and ii. a removable storage component coupled to the main storagecomponent for temporarily storing base images; wherein the removablestorage component temporarily stores a new uncompressed base image,while the uncompressed base image is compressed using the newuncompressed base image.